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rocPRIM

The rocPRIM is a header-only library providing HIP parallel primitives for developing performant GPU-accelerated code on AMD ROCm platform.

Requirements

  • Git
  • CMake (3.5.1 or later)
  • AMD ROCm platform (1.8.2 or later)
    • Including HCC compiler, which must be set as C++ compiler on ROCm platform.

Optional:

  • GTest
    • Required only for tests. Building tests is enabled by default.
    • It will be automatically downloaded and built by cmake script.
  • Google Benchmark
    • Required only for benchmarks. Building benchmarks is off by default.
    • It will be automatically downloaded and built by cmake script.

Build and Install

git clone https://github.com/ROCmSoftwarePlatform/rocPRIM.git

# Go to rocPRIM directory, create and go to the build directory.
cd rocPRIM; mkdir build; cd build

# Configure rocPRIM, setup options for your system.
# Build options:
#   BUILD_TEST - on by default,
#   BUILD_BENCHMARK - off by default.
#
# ! IMPORTANT !
# On ROCm platform set C++ compiler to HCC. You can do it by adding 'CXX=<path-to-hcc>'
# before 'cmake' or setting cmake option 'CMAKE_CXX_COMPILER' to path to the HCC compiler.
#
[CXX=hcc] cmake -DBUILD_BENCHMARK=ON ../. # or cmake-gui ../.

# Build
make -j4

# Optionally, run tests if they're enabled.
ctest --output-on-failure

# Install
[sudo] make install

Using rocPRIM

Include <rocprim/rocprim.hpp> header:

#include <rocprim/rocprim.hpp>

Recommended way of including rocPRIM into a CMake project is by using its package configuration files. rocPRIM package name is rocprim.

# "/opt/rocm" - default install prefix
find_package(rocprim REQUIRED CONFIG PATHS "/opt/rocm/rocprim")

...

# Includes only rocPRIM headers, HIP libraries have
# to be linked manually by user
target_link_libraries(<your_target> roc::rocprim)

# Includes rocPRIM headers and required HIP dependencies
target_link_libraries(<your_target> roc::rocprim_hip)

Running Unit Tests

# Go to rocPRIM build directory
cd rocPRIM; cd build

# To run all tests
ctest

# To run unit tests for rocPRIM
./test/rocprim/<unit-test-name>

Running Benchmarks

# Go to rocPRIM build directory
cd rocPRIM; cd build

# To run benchmark for warp functions:
# Further option can be found using --help
# [] Fields are optional
./benchmark/benchmark_warp_<function_name> [--size <size>] [--trials <trials>]

# To run benchmark for block functions:
# Further option can be found using --help
# [] Fields are optional
./benchmark/benchmark_block_<function_name> [--size <size>] [--trials <trials>]

# To run benchmark for device functions:
# Further option can be found using --help
# [] Fields are optional
./benchmark/benchmark_device_<function_name> [--size <size>] [--trials <trials>]

Performance configuration

Most of device-wide primitives provided by rocPRIM can be tuned for different AMD device, different types or different operations using compile-time configuration structures passed to them as a template parameter. Main "knobs" are usually size of the block and number of items processed by a single thread.

rocPRIM has built-in default configurations for each of its primitives. In order to use included configurations user should define macro ROCPRIM_TARGET_ARCH to 803 if algorithms should be optimized for gfx803 GCN version, or to 900 for gfx900.

Documentation

# go to rocPRIM doc directory
cd rocPRIM; cd doc

# run doxygen
doxygen Doxyfile

# open html/index.html

hipCUB

hipCUB is a thin wrapper library on top of rocPRIM or CUB. It enables developers to port project that uses CUB library to the HIP layer and to run them on AMD hardware. In ROCm environment hipCUB uses rocPRIM library as the backend, however, on CUDA platforms it uses CUB instead.

Support

Bugs and feature requests can be reported through the issue tracker.

Contributions and License

Contributions of any kind are most welcome! More details are found at CONTRIBUTING and LICENSE.

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